TY  - JOUR
A1  - van Velzen, Ellen
A1  - Gaedke, Ursula
T1  - Reversed predator-prey cycles are driven by the amplitude of prey oscillations
JF  - Ecology and evolution
N2  - Ecoevolutionary feedbacks in predator-prey systems have been shown to qualitatively alter predator-prey dynamics. As a striking example, defense-offense coevolution can reverse predator-prey cycles, so predator peaks precede prey peaks rather than vice versa. However, this has only rarely been shown in either model studies or empirical systems. Here, we investigate whether this rarity is a fundamental feature of reversed cycles by exploring under which conditions they should be found. For this, we first identify potential conditions and parameter ranges most likely to result in reversed cycles by developing a new measure, the effective prey biomass, which combines prey biomass with prey and predator traits, and represents the prey biomass as perceived by the predator. We show that predator dynamics always follow the dynamics of the effective prey biomass with a classic 1/4-phase lag. From this key insight, it follows that in reversed cycles (i.e., -lag), the dynamics of the actual and the effective prey biomass must be in antiphase with each other, that is, the effective prey biomass must be highest when actual prey biomass is lowest, and vice versa. Based on this, we predict that reversed cycles should be found mainly when oscillations in actual prey biomass are small and thus have limited impact on the dynamics of the effective prey biomass, which are mainly driven by trait changes. We then confirm this prediction using numerical simulations of a coevolutionary predator-prey system, varying the amplitude of the oscillations in prey biomass: Reversed cycles are consistently associated with regions of parameter space leading to small-amplitude prey oscillations, offering a specific and highly testable prediction for conditions under which reversed cycles should occur in natural systems.
KW  - coevolution
KW  - ecoevolutionary dynamics
KW  - predator-prey dynamics
KW  - top-down control
Y1  - 2018
U6  - https://doi.org/10.1002/ece3.4184
SN  - 2045-7758
VL  - 8
IS  - 12
SP  - 6317
EP  - 6329
PB  - Wiley
CY  - Hoboken
ER  - 
TY  - JOUR
A1  - van Velzen, Ellen
A1  - Thieser, Tamara
A1  - Berendonk, Thomas U.
A1  - Weitere, Markus
A1  - Gaedke, Ursula
T1  - Inducible defense destabilizes predator–prey dynamics
BT  - the importance of multiple predators
JF  - Oikos
N2  - Phenotypic plasticity in prey can have a dramatic impact on predator-prey dynamics, e.g. by inducible defense against temporally varying levels of predation. Previous work has overwhelmingly shown that this effect is stabilizing: inducible defenses dampen the amplitudes of population oscillations or eliminate them altogether. However, such studies have neglected scenarios where being protected against one predator increases vulnerability to another (incompatible defense). Here we develop a model for such a scenario, using two distinct prey phenotypes and two predator species. Each prey phenotype is defended against one of the predators, and vulnerable to the other. In strong contrast with previous studies on the dynamic effects of plasticity involving a single predator, we find that increasing the level of plasticity consistently destabilizes the system, as measured by the amplitude of oscillations and the coefficients of variation of both total prey and total predator biomasses. We explain this unexpected and seemingly counterintuitive result by showing that plasticity causes synchronization between the two prey phenotypes (and, through this, between the predators), thus increasing the temporal variability in biomass dynamics. These results challenge the common view that plasticity should always have a stabilizing effect on biomass dynamics: adding a single predator-prey interaction to an established model structure gives rise to a system where different mechanisms may be at play, leading to dramatically different outcomes.
KW  - phenotypic plasticity
KW  - inducible defense
KW  - stability
KW  - synchronization
KW  - predator-prey dynamics
Y1  - 2018
U6  - https://doi.org/10.1111/oik.04868
SN  - 0030-1299
SN  - 1600-0706
VL  - 127
IS  - 11
SP  - 1551
EP  - 1562
PB  - Wiley
CY  - Hoboken
ER  - 
TY  - JOUR
A1  - van Velzen, Ellen
A1  - Gaedke, Ursula
T1  - Reversed predator
BT  - prey cycles are driven by the amplitude of prey oscillations
JF  - Ecology and Evolution
N2  - Ecoevolutionary feedbacks in predator–prey systems have been shown to qualitatively alter predator–prey dynamics. As a striking example, defense–offense coevolution can reverse predator–prey cycles, so predator peaks precede prey peaks rather than vice versa. However, this has only rarely been shown in either model studies or empirical systems. Here, we investigate whether this rarity is a fundamental feature of reversed cycles by exploring under which conditions they should be found. For this, we first identify potential conditions and parameter ranges most likely to result in reversed cycles by developing a new measure, the effective prey biomass, which combines prey biomass with prey and predator traits, and represents the prey biomass as perceived by the predator. We show that predator dynamics always follow the dynamics of the effective prey biomass with a classic ¼‐phase lag. From this key insight, it follows that in reversed cycles (i.e., ¾‐lag), the dynamics of the actual and the effective prey biomass must be in antiphase with each other, that is, the effective prey biomass must be highest when actual prey biomass is lowest, and vice versa. Based on this, we predict that reversed cycles should be found mainly when oscillations in actual prey biomass are small and thus have limited impact on the dynamics of the effective prey biomass, which are mainly driven by trait changes. We then confirm this prediction using numerical simulations of a coevolutionary predator–prey system, varying the amplitude of the oscillations in prey biomass: Reversed cycles are consistently associated with regions of parameter space leading to small‐amplitude prey oscillations, offering a specific and highly testable prediction for conditions under which reversed cycles should occur in natural systems.
KW  - coevolution
KW  - ecoevolutionary dynamics
KW  - predator-prey dynamics
KW  - top-down control
Y1  - 2018
U6  - https://doi.org/10.1002/ece3.4184
SN  - 2045-7758
SP  - 1
EP  - 13
PB  - Wiley
CY  - Hoboken
ER  -